secondary winding - ορισμός. Τι είναι το secondary winding
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Τι (ποιος) είναι secondary winding - ορισμός

ELECTRICAL DEVICE THAT TRANSFERS ENERGY THROUGH ELECTROMAGNETIC INDUCTION FROM ONE CIRCUIT TO ANOTHER CIRCUIT
AC transformer; Powerstat; Primary coil; Secondary Coil; Transformers (electrical); Transfomer; Line transformer; Tap (transformer); Electrical transformer; Air-core transformer; Primary winding; Secondary winding; Voltage conversion; Power transformer; Secondary coil; Power drums; Step down transformer; Step up transformer; Electric transformer; Ideal transformer; Step-down transformer; Step-up transformer; Primary circuit; Secondary circuit; Xformer; Electricity transformer; Magnetizing current; Displacement factor; Unit auxiliary transformer; Dry-type transformer; Dry type transformer; Trafo; TRAFO; Transformer turn ratio; Transformer ratio; Turn ratio; Xfmr; Oil natural, air natural; Oil natural, air forced; Oil forced, air forced; Stepdown transformer; Voltage to Hertz ratio; Overfluxing; Applications of transformers
  • "E" shaped plates for transformer cores developed by Westinghouse
  • Camouflaged]] transformer in [[Langley City]]
  • Interleaved E-I transformer laminations showing air gap and flux paths
  • Ideal transformer connected with source ''V''<sub>''P''</sub> on primary and load impedance ''Z''<sub>''L''</sub> on secondary, where 0&nbsp;<&nbsp;''Z''<sub>''L''</sub>&nbsp;<&nbsp;∞.
  • An [[electrical substation]] in [[Melbourne]], [[Australia]]
showing three of five 220&nbsp;kV – 66&nbsp;kV transformers, each with a capacity of 150&nbsp;MVA
  • Power transformer overexcitation condition caused by decreased frequency; flux (green), iron core's magnetic characteristics (red) and magnetizing current (blue).
  • Substation transformer undergoing testing.
  • Transformer at the [[Limestone Generating Station]] in [[Manitoba]], Canada
  • Leakage flux of a transformer
  • Core form = core type; shell form = shell type
  • Schematic of a large oil-filled power transformer 1. Tank 2. Lid
3. Conservator tank 4. Oil level indicator 5. Buchholz relay for detecting gas bubbles after an internal fault 6. Piping
7. Tap changer 8. Drive motor for tap changer 9. Drive shaft for tap changer
10. High voltage (HV) bushing
11. High voltage bushing current transformers
12. Low voltage (LV) bushing
13. Low voltage current transformers
14. Bushing voltage-transformer for metering
15. Core 16. Yoke of the core
17. Limbs connect the yokes and hold them up 18. Coils
19. Internal wiring between coils and tapchanger
20. Oil release valve
21. Vacuum valve

Compensation winding         
  • C. Cross section of DC motor with compensation windings showing magnetic flux due to armature windings.
  • E. Cross section of DC motor with compensation windings showing magnetic flux due to field and armature under heavy load with compensation windings.  The flux in the gap has been restored.
  • D. Cross section of DC motor with compensation windings showing magnetic flux due to field and armature under heavy load.  The flux in the gap has shifted.
  • B. Cross section of DC motor with compensation windings showing magnetic flux due to field windings.
WINDING IN THE POLE FACE OF A MOTOR
Compensation Winding
A compensation winding in a DC shunt motor is a winding in the field pole face plate that carries armature current to reduce stator field distortion. Its purpose is to reduce brush arcing and erosion in DC motors that are operated with weak fields, variable heavy loads or reversing operation such as steel-mill motors.
Coil winding technology         
  • Winding machine
  • 293x293px
  • 281x281px
  • 290x290px
  • Winding nozzle in winding position
  • Winding nozzle in position for termination
  • Orthocyclic winding of a round coil
  • Schematics of an open winding space using a flyer winding process for chained pools
  • Concept of an end plated insulated stator
  • Determination of the necessary space between teeth depending on the wire gauge (Source: Aumann GmbH)
  • Laminations after assembly into a stator
  • Stators with different winding topologies
  • Comparison of concentrated and distributed windings
  • Examples for different Designs of EC-Stators (Source: Technoexpert Dresden)
  • Example for a lead from for a full sheet metal package stator displaying several design characteristics
  • Verschieden isolierte Vollblechschnitte
  • fill factor
MANUFACTURE OF ELECTROMAGNETIC COILS
Coil Winding Technology; Orthocyclic coil winding; Electrical degrees
In electrical engineering, coil winding is the manufacture of electromagnetic coils. Coils are used as components of circuits, and to provide the magnetic field of motors, transformers, and generators, and in the manufacture of loudspeakers and microphones.
secondary colour         
COLOR MADE BY MIXING TWO PRIMARY COLORS
Secondary colour; Secondary colors; Secondary colours; Primary and secondary color; Subtractive secondary colors
¦ noun a colour resulting from the mixing of two primary colours.

Βικιπαίδεια

Transformer

A transformer is a passive component that transfers electrical energy from one electrical circuit to another circuit, or multiple circuits. A varying current in any coil of the transformer produces a varying magnetic flux in the transformer's core, which induces a varying electromotive force (EMF) across any other coils wound around the same core. Electrical energy can be transferred between separate coils without a metallic (conductive) connection between the two circuits. Faraday's law of induction, discovered in 1831, describes the induced voltage effect in any coil due to a changing magnetic flux encircled by the coil.

Transformers are used to change AC voltage levels, such transformers being termed step-up or step-down type to increase or decrease voltage level, respectively. Transformers can also be used to provide galvanic isolation between circuits as well as to couple stages of signal-processing circuits. Since the invention of the first constant-potential transformer in 1885, transformers have become essential for the transmission, distribution, and utilization of alternating current electric power. A wide range of transformer designs is encountered in electronic and electric power applications. Transformers range in size from RF transformers less than a cubic centimeter in volume, to units weighing hundreds of tons used to interconnect the power grid.